CN102448394A - Patient-specific joint arthroplasty devices for ligament repair - Google Patents

Patient-specific joint arthroplasty devices for ligament repair Download PDF

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Publication number
CN102448394A
CN102448394A CN2010800239351A CN201080023935A CN102448394A CN 102448394 A CN102448394 A CN 102448394A CN 2010800239351 A CN2010800239351 A CN 2010800239351A CN 201080023935 A CN201080023935 A CN 201080023935A CN 102448394 A CN102448394 A CN 102448394A
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tunnel
ligament
template
graft
patient
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CN102448394B (en
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R·博雅斯基
P·朗
D·斯泰尼斯
W·菲茨
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Imaging Therapeutics Inc
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Imaging Therapeutics Inc
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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B34/00Computer-aided surgery; Manipulators or robots specially adapted for use in surgery
    • A61B34/10Computer-aided planning, simulation or modelling of surgical operations
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B17/00Surgical instruments, devices or methods, e.g. tourniquets
    • A61B17/16Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
    • A61B17/17Guides or aligning means for drills, mills, pins or wires
    • A61B17/1714Guides or aligning means for drills, mills, pins or wires for applying tendons or ligaments
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B17/00Surgical instruments, devices or methods, e.g. tourniquets
    • A61B17/16Bone cutting, breaking or removal means other than saws, e.g. Osteoclasts; Drills or chisels for bones; Trepans
    • A61B17/17Guides or aligning means for drills, mills, pins or wires
    • A61B17/1739Guides or aligning means for drills, mills, pins or wires specially adapted for particular parts of the body
    • A61B17/1764Guides or aligning means for drills, mills, pins or wires specially adapted for particular parts of the body for the knee
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/103Detecting, measuring or recording devices for testing the shape, pattern, colour, size or movement of the body or parts thereof, for diagnostic purposes
    • A61B5/11Measuring movement of the entire body or parts thereof, e.g. head or hand tremor, mobility of a limb
    • A61B5/1121Determining geometric values, e.g. centre of rotation or angular range of movement
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61FFILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
    • A61F2/00Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
    • A61F2/02Prostheses implantable into the body
    • A61F2/30Joints
    • A61F2/30756Cartilage endoprostheses
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61FFILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
    • A61F2/00Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
    • A61F2/02Prostheses implantable into the body
    • A61F2/30Joints
    • A61F2/3094Designing or manufacturing processes
    • A61F2/30942Designing or manufacturing processes for designing or making customized prostheses, e.g. using templates, CT or NMR scans, finite-element analysis or CAD-CAM techniques
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B17/00Surgical instruments, devices or methods, e.g. tourniquets
    • A61B17/56Surgical instruments or methods for treatment of bones or joints; Devices specially adapted therefor
    • A61B2017/568Surgical instruments or methods for treatment of bones or joints; Devices specially adapted therefor produced with shape and dimensions specific for an individual patient
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B34/00Computer-aided surgery; Manipulators or robots specially adapted for use in surgery
    • A61B34/10Computer-aided planning, simulation or modelling of surgical operations
    • A61B2034/101Computer-aided simulation of surgical operations
    • A61B2034/105Modelling of the patient, e.g. for ligaments or bones
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B34/00Computer-aided surgery; Manipulators or robots specially adapted for use in surgery
    • A61B34/10Computer-aided planning, simulation or modelling of surgical operations
    • A61B2034/108Computer aided selection or customisation of medical implants or cutting guides
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B34/00Computer-aided surgery; Manipulators or robots specially adapted for use in surgery
    • A61B34/20Surgical navigation systems; Devices for tracking or guiding surgical instruments, e.g. for frameless stereotaxis
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/103Detecting, measuring or recording devices for testing the shape, pattern, colour, size or movement of the body or parts thereof, for diagnostic purposes
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/45For evaluating or diagnosing the musculoskeletal system or teeth
    • A61B5/4504Bones
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/45For evaluating or diagnosing the musculoskeletal system or teeth
    • A61B5/4514Cartilage
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/45For evaluating or diagnosing the musculoskeletal system or teeth
    • A61B5/4523Tendons
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/45For evaluating or diagnosing the musculoskeletal system or teeth
    • A61B5/4533Ligaments
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61FFILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
    • A61F2/00Filters implantable into blood vessels; Prostheses, i.e. artificial substitutes or replacements for parts of the body; Appliances for connecting them with the body; Devices providing patency to, or preventing collapsing of, tubular structures of the body, e.g. stents
    • A61F2/02Prostheses implantable into the body
    • A61F2/08Muscles; Tendons; Ligaments

Abstract

Disclosed herein are methods, compositions and tools for repairing, replacing or otherwise treating bone ligaments using devices designed from patient-specific information, including without limitation, surgical alignment instruments that have a surface that conforms to at least a portion of a patient's bone, cartilage or other component of the joint or ligament being treated.

Description

The exclusive arthroplasty device of patient that is used for ligament repair
The cross reference of related application
The title that the application requires on April 16th, 2009 to submit to is the U.S. Provisional Patent Application No.61/169 of " Patient-Specific Joint Arthroplasty Devices for Ligament Repair ", 823 rights and interests and priority.
In addition, the title of submitting in the application and on February 6th, 2007 be that " Patient Selectable Joint Arthroplasty Devices and Surgical Tools " (' 745 applied for) U.S. Patent application No.11/671,745 is relevant.
This ' 745 application requires the rights and interests of following patent: the title of submitting on February 6th, 2006 is the U.S. Patent application No.60/765 of " Surgical Tools for Performing Joint Arthroplasty ", 592; The title that on March 23rd, 2006 submitted to is the U.S. Patent application No.60/785 of " Surgical Tools for Performing Joint Arthroplasty ", 168; And the title that on March 31st, 2006 submitted to is the U.S. Patent application No.60/788 of " Surgical Tools for Performing Joint Arthroplasty ", 339.
Above-mentioned each application is incorporated its full content mode by reference into this paper for all orders.
Technical field
Embodiment described herein relates to and is used for operating straightening method, system and the device relevant with articular ligament.Some embodiments comprise by the operation mould of the exclusive design data of patient so that help the reparation or the replacement of this type of ligament.
Background technology
Exist continue to increase quantity for repairing, rebuild, replace or otherwise treat the operating situation that ligament (for example anterior cruciate ligament (" ACL ") and posterior cruciate ligament (" PCL ")) is implemented.But the surgeon who implements this type of operation has any problem in other operating procedure for example suitably placing graft or implement.
In the situation of ACL and PCL graft, placing related tunnel possibly be difficult to hold graft.For example, according to report, the graft of on femur, placing too forward is the common cause of ACL reconstruction failure.Some research proposals are placed the femur tunnel more accurately can improve the kinesiology performance.Place tibia and femur tunnel more accurately and can reduce the incidence rate of graft failure, and can reduce and rebuild observed long-term degradation afterwards.Also there be other difficult problem related with this type of operation.For example, in some cases, being difficult to locate will be from the tissue that wherein extracts graft or suitably by the sized graft.
Brief summary of the invention
Embodiment described herein is provided for implementing surgical operation to replace, to repair or otherwise to treat the new device and the method for the ligament related with osteoarthrosis.
In one aspect, some embodiment relates to the method that is used for ligament repair, and this method comprises obtains at least one surperficial electronic image data related with ligament.Construct first template based on said view data at least in part.Said first template has at least one contact surface of at least a portion that meets said surface.Said first template comprises at least one guiding device of the motion that is used to guide the related operating theater instruments of ligament repair.
In some embodiments, ligament can be anterior cruciate ligament or posterior cruciate ligament.Said method can also comprise the position, tunnel of confirming the implantation of ligament thing.Confirm that the position, tunnel can comprise the starting point of the ligament of identification on first articular surface and at the second joint lip-deep dead-centre position relative with said first articular surface.Confirm position, said tunnel can comprise based on the remainder of said view data identification bony landmark and ligament at least one of them.Said surface can be adjacent with position, said tunnel or non-bearing surface.Said first template can comprise one or more pins and/or awl guide hole; Said method comprises that also the said template in location is so that said at least one contact surface contacts with said at least one part on said surface; And (for example make up; Get out) the ligament tunnel, for example, wherein come pilot bore hole through the awl guide hole.The pin on said first template and/or the shape of awl guide hole, position and towards at least one of them can be at least in part based on the distance of said tunnel to adjacent cortical bone.Said awl guide hole can comprise stop, so that reach the drilling depth of expectation.Can before operation, obtain said view data.Can scan through CT scan or MRI and obtain said view data.Can be in the joint flexing, joint stretching, extension, joint abduction, intraarticular is received and/or obtain said view data during the rotation of joint.Said method can also comprise based on said view data identification graft obtains the position, and use said first template guide from said graft obtain the position obtain ligament and skeleton at least one of them.Said method can also comprise makes second template and the said first template cross reference so that on the second surface related with ligament, aim at the position of said second template; Said second template comprises at least one guiding device, and uses said at least one guiding device of said second template to guide the motion of said apparatus with respect to said guiding device.Said first and second surfaces can be relative articular surfaces.Said first surface can be that femoral surface and said second surface can be the tibia surfaces.Said first template can comprise tissue retractor.Said tissue retractor can be flange or the dilator on the said template.Said template can be used for single bundle or the two-beam ligament is rebuild.
In some embodiments, this method can also comprise the electronic image data of obtaining the joint and confirm the shape of said at least one contact surface of said first template at least in part based on the electronic image data.Firmly can comprise and use Kirschner wire, screw, anchor and/or pin or the drill bit of staying original place on the joint.Firmly can comprise said contact surface is positioned at least one or a plurality of concave surface and the convex surface on the joint.Firmly can comprise with said contact surface be positioned on the joint at least one concave surface and at least on the convex surface.Firmly can comprise said contact surface is positioned on the arthritis part in joint at least in part.Firmly can comprise said contact surface is positioned on the normal part position and the interface between the arthritis part in joint at least in part.Firmly can comprise at least in part and locate said contact surface with respect to anatomical features.Said anatomical features can be coaster, intercondylar fossa, medial condyle and lateral condyle, inboard coaster and outside coaster, medial tibial platform and lateral tibial platform, recessed, acetabular fossa, trident cartilage, acetabular bone wall or limbus of acetabulum.Said contact surface is positioned to comprise on the surface in joint, said contact surface is positioned at least in part on the normal part in joint.Confirm the position of said guiding device on said template can be at least in part based on ligament balance and/or with optimization go down on one's knees the gap with stretch the knee joint gap at least one of them.Said method comprises that also the pin that uses pad for example, ratchet means and permission rotation is to adjust the position of said guiding device with respect to the joint in operation.
In some embodiments, the distal femoral component of confirming expectation rotates the one or more anatomical axis and/or the plane that can comprise that measurement is relevant with the distal femoral component rotation.One or more anatomical axis and/or plane can comprise femur epicondyle axle, white edge line and/or femoral-posterior condyles axle.Said guiding device can instruct femoral cut, and said method also comprises makes the rotation of said template so that said femoral cut is parallel with tibial cut, wherein applies basically equal pulling force with lateral ligament and soft tissue in the inboard and the outside from inboard.
In some embodiments, the tibial component of confirming expectation rotates the one or more anatomical axis and/or the plane that can comprise that measurement is relevant with the tibial component rotation.Said one or more anatomical axis and/or plane can comprise the inboard 1/3rd of the antero posterior axis and/or the tibial tubercle bone of tibia.Said guiding device can instruct femoral cut, and said method also comprises makes the rotation of said template so that said femoral cut is parallel with tibial cut, wherein applies basically equal pulling force with lateral ligament and soft tissue in the inboard and the outside from inboard.
In some embodiments, a kind of method that is used for arthroplasty comprises provides template, and said template comprises and being used at least in part based at least one surperficial surface of isotropic basically input data connecting joints.Said surface can be basically and one or more parts couplings of articular surface or whole articular surface (that is, meet or para-position).Said template can comprise at least one guiding device of the motion that is used to instruct operating theater instruments.
In some embodiments, can use fusion or the basic isotropism MRI of the plane of delineation and spiral CT to obtain said input data.
Embodiment described herein and aspect any one in, said joint can be and be not limited to knee joint, shoulder, hip, cervical vertebra, elbow, ankle, foot, toe, hands, wrist or finger.
Some embodiments can comprise multiple additional characteristic, as the operation in the adjustment multiple size, towards or relative position.For example, apparatus can be located one or more tunnels, simultaneously can based on graft length and position with definite tunnel in operation towards.Inlet and the definite tunnel that apparatus can also come localized tunnel through adjustment in the optional operation towards.
In some embodiments, first tunnel can be used in be connected to identical articular surface related or with related second tunnel of different articular surfaces or reference is provided for it.
In some embodiments, for example can before for example intra-operative or operation, assess and/or improve the kinesiology performance in joint through the image and/or the model in assessment joint.For example; Can carry out simulation through the biological motion that shows the patient; And can the kinesiology performance be added to and place to evaluate best possible graft tunnel on the imaging data, the graft length that for example expectation is provided, the graft thickness of expectation, graft intensity and/or one or more further feature of expectation are placed in the graft tunnel that this best is possible.
In some embodiments, can carry out finite element analysis based on imaging data, kinesiology performance information and/or the model (including but not limited to the model of joint motions and/or articulation structure) in patient joint.For example, can carry out this finite element analysis to confirm bone strength, the bone strength of confirming specifically to be used for the two-beam technology is to guarantee bone material enough between the tunnel.This finite element analysis can comprise the analysis of one or more parameters, and these one or more parameters comprise and are not limited to one or more in graft length, graft thickness, osseous tunnel length, osseous tunnel thickness, weight in patients, height, sex, multiple active active force, bone volume, bone thickness, bone structure parameter and the bone density.Can carry out multivariate analysis to multiple loading condition maybe tunnel location with identification the best that failed probability is minimum in the future.
Some embodiments can comprise that pick off, signal thing, RF label and other attachment device and assembly are to help for example balance, surgical navigational and/or one or more other process and target.
Hereinafter is described some embodiments in more detail.The characteristic that it being understood that multiple embodiments described herein is not mutually exclusive, and can exist with multiple combination and spread pattern.
The accompanying drawing summary
Can more easily understand aforementioned characteristic through describing in detail with reference to hereinafter with reference to accompanying drawing, wherein:
Fig. 1-3 diagram uses the guiding template to implement ligament repair according to embodiments more of the present invention.
Fig. 4 is according to embodiments more of the present invention, the side perspective view of the embodiment of the exclusive apparatus of patient that when the ACL intra-operative makes up (for example, getting out) tibial tunnel, uses.
Fig. 5-the 7th, the side perspective view according to the embodiment shown in Fig. 4 of embodiments more of the present invention wherein illustrates counterpart with the partially transparent view.
Fig. 8 is according to embodiments more of the present invention, the side perspective view of the embodiment of the exclusive apparatus of patient that when the ACL intra-operative makes up (for example, getting out) femur tunnel, uses.
Fig. 9 is according to the side perspective view of the embodiment shown in Fig. 8 of embodiments more of the present invention, wherein with the partially transparent view counterpart is shown.
Figure 10 is according to the side perspective view of the embodiment shown in Fig. 8 of embodiments more of the present invention, wherein with transparent view counterpart and condyle of femur is shown.
Figure 11 is the side perspective view according to the embodiment shown in Fig. 8 of embodiments more of the present invention, wherein in the outlet in the tunnel of femur shown in the condyle of femur.
Figure 12-the 13rd, according to embodiments more of the present invention, the side perspective view (observing vertically) of the partially transparent of the embodiment of the exclusive apparatus of patient that when two-beam ACL intra-operative makes up the femur tunnel, uses from DF.
Figure 14-the 15th, according to embodiments more of the present invention, the side perspective view of the partially transparent of the embodiment of the exclusive apparatus of patient that when two-beam ACL intra-operative makes up tibial tunnel, uses.
Figure 16 is according to embodiments more of the present invention, the side perspective view (observing vertically from DF) of the partially transparent of the alternative embodiment of the exclusive apparatus of patient that when two-beam ACL intra-operative makes up the femur tunnel, uses.
Figure 17 is the alternative view according to the device shown in Figure 16 of embodiments more of the present invention.
Figure 18-19 diagram according to embodiments more of the present invention be designed to avoid the use of during to the ballistic template of ligamentum cruciatum.
Detailed Description Of The Invention
Can be by the anatomical structure of individual patient design operation tool and other device so that the device with following characteristic to be provided: have the cooperation of customization or carry out the function of customization for this patient; The anatomical structure of improving or optimizing is provided for this patient; For this patient provides the kinesiology performance of improving or optimizing, and/or be provided with using with standard implant, instrument, device and surgical operation and/or other method.These operation tools include but not limited to aim at guiding device, and these operation tools are particularly suited for reparation, replacement or other treatment of ligament (comprise and be not limited to anterior cruciate ligament (" ACL ") and/or posterior cruciate ligament (" PCL ")).
These operation tools (for example, aiming at guiding device) and other device can comprise and be not limited to template, anchor clamps and/or mould (comprising the guiding mould).In this manual; Only if context points out separately, otherwise term " template ", " anchor clamps ", " mould ", " guiding mould " and " guiding template " can exchange to make in detailed Description Of The Invention and accompanying claims and be used for describing the particular than the operation tool of major types.
The exclusive operation tool of patient comprises a series of embodiment with other device.For example, can completely or partially be directed against patient customized this kind tool and device, in the situation of the ligament guiding device that matches in position profile with the surface in joint and ligament.In addition; Other instrument can only comprise one or several sizes or the characteristic by the exclusive design data of patient with device; In the situation of the implant on the surface that has radius of curvature in coronal plane but not in the sagittal plane, described size or characteristic are based on the corresponding radius of curvature on the surface of patient's in the coronal plane anatomical structure.In some embodiments; These instruments and device can be at least in part design to incorporate one or more design features into based on patient's exclusive data, that these one or more design features produce is ideal, optimize or improved anatomical structure, kinesiology function and/or other surgical effect.These situation only are exemplary, and the combination of many other embodiments and embodiment all is possible.
Except others, technology described herein, instrument, implant, apparatus and method can realize that the customization of cartilage and ligament repair is for example to be fit to concrete experimenter aspect size, cartilage thickness and/or the curvature.Therefore, except others, the invasive methods that embodiment described herein is provided for ligament repair, replaces and controls.Embodiment preferred is an invasive, although the disclosed notion of this paper can also be used with more invasive techniques jointly.In addition; Be different from current technology; Preferred embodiment described herein through provide realize implant with on every side or between adjacent cartilage and/or the subchondral bone accurately or the accurate location of approximate dissection structure matching and the anatomic marker related or aim at the operation tool that produces reliable and improved surgical effect with it with ligament, can help to produce efficient and accurate operating procedure.
1. ligament repair, replacement and/or treatment
For ligament repair and replacement, the guiding mould can be used for method of planning and the intervention that makes arrangements for surgery, and implements operation and get involved.In some embodiments, can in one or more operating procedures, use one or more guiding moulds to repair, replace, rebuild or otherwise treat ACL or PCL.Use embodiment described herein can also handle other tendon and ligament injury, for example comprise shoulder sleeve, ankle tendon and ligament injury occurred frequently and that take place frequently.
1.1 ACL treatment
ACL is the continuum that does not have significantly to restraint the fiber of morphological characteristic.Its microdissection structure is made up of many collagen fiber that are combined into bigger bundle.Describe although lack anatomy, fiber alignment is divided into two thin portions or bundle in " on the function ": preceding inboard band and the outside, back band.The proximal part that the fiber of preceding inboard band ends from the femur attachment region passes through to arrive the preceding inboard of tibia attachment region.The outside, back band fiber is attached to femur and is attached to tibia in the outside, back at far-end.When knee extension, back outside band is tightened, and when knee flexion, preceding inboard be with to become tighten.Because internal structure and attachment area on femur and the tibia, ACL to the anterior displacement of tibia and internal rotation, in turn over angle and valgus angle and knee overextension constraint is provided.
Current estimation shows annual 100, the 000 routine ACL reconstruction operations of implementing of the U.S..Many in these damages is during sports, to take place, and these sports comprise deceleration, reverse, cut-out and jumping exercise.Since the mandatory rotation (wherein knee full extension) or the mandatory hyperextension of femur on the excessive stress that turns up, the fixed tibia, and make ligament impaired.The scope of ACL damage is sprained (I level or II level) to fracture (III level) fully from the part.
Because ACL is in IA position, ACL healing potentiality are low.The joint external ligament experiences a series of inflammation phase, proliferative phase and reinvents the stage and heal, and this causes the formation of organic scar tissue.The formation of local hematoma has intensified this process.By contrast, when ACL tore, its synovial membrane sheath was impaired, and blood spreads at intraarticular.Under the situation that does not form blood clot, the regular turn of soft tissue repair can't begin.Disruptive ACL can not form the bridge joint cicatrix after the fracture fully.But, on perished surface, form synovial tissue's layer, and the end that breaks shrinks.
Under the situation of not treating, the symptomatic knee that ACL damage completely possibly cause increasing gradually is unstable, and this causes the recurrent intraarticular damage and finally causes osteoarthritis.
Wherein one or more that the typical treatment of ACL damage can comprise the steps:
1. knee assessment and the damaged affirmation of ACL;
2. graft obtains;
3. the arthroscope of intraarticular disease confirms and treatment;
4. the preparation of intercondylar fossa;
5. osseous tunnel is placed;
6. graft is implanted and is fixing; And
7. wound closure and operation back matters.
Comprise description in the following segmentation to the typical characteristic of each step in these steps.
1.1.1 knee assessment
The knee assessment for example can comprise to be counted through PE and the moving degree of KT-1000 knee joint, anaesthetizes assessment and more impaired knee and offside knee down the patient before the operation.When the complete damaged clinical manifestation of ACL is obvious, can before the arthroscopy part of operation, obtain autograft.
1.1.2 graft obtains
The selection of graft can be decided according to individual surgeon and patient's preference.Commonly, take from its two ends of body graft from the centre 1/3rd of patient's patella tendon and have the bone bolt, although can also use autograft, allograft or the xenograft in other source.When the centre three of the patella tendon that obtains the patient/for the moment, 40% or the graft still less that can get width and be whole patella tendon width are target, and scalpel blade correspondingly is set.For example, when tendon width at least during 25mm, blade is made as at a distance of 10mm.For less patient, can get less a little graft width is target.The place begins at the bone attachment region, and cut the centre 1/3rd along its single from tendon.Can use draw bone-tendon junction and draw the profile at the edge of bone bolt of electric cautery then.To being used to obtain the technology of bone bolt, advantageously obtaining and join to suitably with minimum profile finishing in the osseous tunnel so that bone bolt that can stabilization and reinforcement with reproducible mode.In addition, the risk of advantageously implementing to obtain the Patella fracture at position drops to minimum bone bolt and obtains technology.For example can use to have the oscillating circular saw (Stryker) of diameter as the saw blade of 10mm, it provides the cylindrical bone bolt of different-diameter (9,10 or 11mm).This device can provide following advantage: it is easy and quick (a) to obtain; (b) on the diameter than the renewable cylindrical bone bolt of the little 1mm of corresponding osseous tunnel; (c) reduce patella and obtained the stress riser at position; And (d) because size evenly and is easily inserted graft.But, be to be placed on patient's the skeleton by hand because this installs with other similar device, so device is placed and the placement of bone bolt maybe be different with the placement or the ideal placement of surgeon's expection.In case obtain, can prepare also shaping so that implant at side stage to autograft by the surgeon, or accomplish preparation and shaping, and the surgeon prepare osseous tunnel to receive autograft by the assistant.
Preferably, measure the about 25mm of length from the bone bolt that tibia obtains, and measure about 20 to 22mm from the bone bolt that patella obtains.Can use cylindrical clasfficiator (sizer) to carry out of the simulation of bone bolt through osseous tunnel.Can on demand or expect intercepting bone bolt, till they easily slide through suitable clasfficiator.Less bone bolt (taking from patella usually) is placed in the femur tunnel.Structure uses the single hole of 3/32 drill bit bore for example to pass the cortex surface of bone bolt, makes stitching thread pass this hole.The position in this hole is very near the end of bone bolt, so that better directed control is provided at graft in through the femur tunneling process.In the tibial bone bolt, make three evenly spaced holes, and stitching thread is passed.These holes be perpendicular to one another towards reduce to minimum so that confused ground inserted the chance of the sutures breaks in the process of screw.After the preparation, the total length of typical bone-patella tendon bone graft is about 90 usually to 105mm.The desired length that length that can be through from total graft length, deducting the femur tunnel and intraarticular length are calculated tibial tunnel.A kind of method that solves the length mispairing between graft and the tunnel comprises from tibia obtains extra bone bolt material being used to the inserting femur tunnel, thereby makes effectively in the further recessed femur of whole graft, and reduces graft from the outstanding probability of tibia.This technology can make effectively in the recessed femur of the graft tunnel and reach 8mm, wherein the tibia piece is inserted in the tunnel behind the bone bolt.
1.1.3 the confirmation of intraarticular disease and treatment
Can the assistant when side stage prepares graft, implement operating intraarticular part.Usually, arthroscope is inserted in the preceding outer side entrance of constructing with the outer boundaries of exposing the patella tendon through the flap of shrinking back.Side entrance in before can adopting similar mode to make, and can two inlets all be placed in the edge of existing skin incision.Can when using alternative graft, comprise independent standard arthroscope inlet.ACL rebuilds and comprises high flow of liquid usually, and this can realize via independent sleeve pipe or via the pump through arthroscope.Can implement comprehensively to diagnose arthroscopy to confirm the ACL that tears, and the state of assessment meniscus and articular cartilage.For example can use hook to visit each intraarticular structure, and the image of the taking pictures purpose that is used to confirm.Preferably, treat the intraarticular damage of any association, then carry out ligament then and rebuild.For example, can repair or excise meniscus tear, and if think suitable, for example, can confirm and the treatment articular cartilage damage through chondroplasty or little fracture.
1.1.4 the preparation of intercondylar fossa
In some embodiments, can use the overall diameter resectoscope to remove the residual fraction of the ACL that tears, so that can clearly discern the tibia attachment region.Can remove the ligament mucus to strengthen visibility.Seldom excise fat pad under the kneecap, and protect posterior cruciate ligament (PCL) usually.Can be for example be used for swing resectoscope that soft tissue removes down and begin the intercondylar fossa plasty from the sidewall removing soft tissue and the periosteum of intercondylar fossa directly visual.Can remove the whole surface of outer wall, comprise opening to osseous tunnel.In case fully remove the soft tissue of intercondylar fossa, then can just need supernumerary bone intercondylar fossa plasty to assess, if visual outer wall is had any problem or exist the intercondylar fossa hyperosteogeny possibly clash into and crush-cutting ACL graft, then can implement supernumerary bone intercondylar fossa plasty.Can use arthroscope drill bit or overall diameter resectoscope to implement this operation.Widen if hope the t intercondylar fossa, can introduce the crooked osteotome of Y4-inch through inlet, and can utilize nipper to remove big GUSUIPIAN.Minimum articular cartilage removes and conforms with expectation.Place when for example being used to place pin or awl when depending on visual sign, possibly remove other material so that recognition marks correctly with the pin of structure osseous tunnel, awl and other instrument.For example, advantageously, the posterior edges of clearly discerning intercondylar fossa is to avoid that said " resident ridge (resident ' s ridge) " was misinterpreted as the position, top.This error during visual sign is selected possibly cause in the operation that only depends on visual recognition sign femur tunnel put must be than expectation more forward.
1.1.5 osseous tunnel is placed and preparation
Selecting ideal osseous tunnel position is important step during ACL rebuilds.Normal ACL is made up of a large amount of fibers.Every fibre length difference has different starting points and stop, and is being under the differential tension during the scope of knee kinematics.The graft of replacement ACL comprises parallel fiber.Even optimally selected the placement of osseous tunnel, the fiber of graft still possibly bear length and tensile variation in range of movement.Therefore, the ACL replacement possibly can't be duplicated former ligament.But, the center of osseous tunnel is placed on the most isometric some place makes the stability maximization that can obtain in the motor process.
In case prepared intercondylar fossa, then selected to be used for the position in femur tunnel.In traditional method, the placement in tunnel needs the visual position, top of crossing, and this can be through knee flexion to 70 degree or more improvement the with the patient more.
If expectation uses interference screw to fix, then the osseous tunnel of cortical wall thickness after at least 1 to 2mm is selected to obtain so that support and help prevent thus the rear wall explosion for interference screw provides the back in the position.
For the center in the femur tunnel of locating expectation, can use one or more placement guiding devices, for example cut off the placement guiding device of position, top.For example, more fully describe as hereinafter, can use one or more templates and guiding device, these one or more templates have the surface on the surface that meets patient's anatomical structure, and this guiding device is used for constructing osseous tunnel in the position of expectation.For example can construct the surface that meets of template based on the view data of patient's anatomical structure.
Use meets the template of patient's anatomical structure; Can be for example come accurately to confirm in advance in osseous tunnel position, tunnel diameter and/or the length of tunnel one or multinomial based on the image of patient's anatomical structure, and position, diameter and/or the length that can the characteristic Design of guiding device be become to realize expectation.This guiding device is inserted through side entrance in before attached, before this is attached in the position of side entrance get lowlyer, just be positioned at joint line top and alignment, so that the corresponding surface engagement that meets surface and patient's anatomical structure on the guiding device.Randomly, can be through visual checking and with the position of instrument (for example, using nerve hook) inspection guiding device, to confirm correct position.Select position, suitable localized femur tunnel to guarantee maximum postoperative knee stability.
The intraarticular position of tibial tunnel can be very little to the variable effect of graft length, but its position possibly be important in preventing the intercondylar fossa bump.Generally can make opening outside the joint of tibial tunnel be positioned at center near the intraarticular opening of the anatomical structure center rear side of ACL tibia attachment region.Four anatomical structure signs can be useful for tibial tunnel center, location: the anterior angle of lateral meniscus, medial tibial sour jujube, PCL and ACL stump.The inward flange of anterior angle that can be through the lateral meniscus that continues prolongs straight line with this position, location in the pro-back plane.Can with this point location before the preceding border of PCL 6 to 7mm.In many operations, this tunnel is placed can make the one-time-reach-place of ACL graft, with the outside of contact PCL, but can obviously not depart from because of it.Similarly, when knee was in full extension, it should be unable to rub and also can not clash into the inboard of lateral femur condyle or the top of intercondylar fossa.Preceding graft is placed and possibly caused clashing into and the breakage of graft subsequently.
1.1.6 graft is sent and is fixed
Under arthroscope is observed, utilize the cephalad traction on the near-end stitching thread that graft is delivered in the femur tunnel.Porous surface is placed on the preceding outside, so the rear side of collagen fiber in the femur tunnel of new ligament.When oral area was visually observed the bone bolt of using a labelling in the early time and ligament junction in the tunnel, graft put in place fully.Can use tubular interference screw fixation implant, although other alternative fixing means also is available.
1.1.7 wound closure and operation back matters
In the final step of operation, use the bony defect that produces because of autograft (for example, in patella) from the bone marrow transplantation of tibial tunnel acquisition.Can be this be damaged closed ligament tissue with the graft fix in position.Under the situation that does not shorten tendon, but make the patella tendon loosely approaching again the gap of any sense of touch is reduced to minimum.In independent each layer with accessory tendon, subcutaneous tissue and skin closure.After the operation, restore several weeks.Rebuild relevant post-operative complication with ACL and for example can comprise, in lost-motion function, recurrent instability and kneecap thigh dysfunction and the pain one or multinomial.
The motion of the scope that can't regain one's integrity after ACL rebuilds maybe be relevant inadequately with operation mistake, joint fibrosis, long-term immobilization or participation back-out plan during graft is placed.The error of performance that influences the motion of knee joint scope comprises that the placement of tibial tunnel is forward, the incorrect tensioning of graft bump and graft.Therefore, the accurate placement in femur tunnel is important.If femur tunnel location is too forward, then it possibly limit knee flexion, and if will place lean on very much after, then it possibly retrain knee extension.When tibial tunnel being located too forward, the ACL graft possibly clash into intercondylar fossa, thus the constraint knee extension.Pass in time, intercondylar fossa has the influence of crush-cutting to graft, and causes its breakage.Suitable intercondylar fossa plasty and carefully select the osseous tunnel position can the risk of bump be reduced to minimum.
1.2 be used for the exclusive tool and method of patient of ACL operation
In embodiments more described herein, can select and/or the design guide template so that can in femur and tibia, realize pin-point accuracy, renewable and invasive graft tunnel.
In one embodiment, before operation, image, like CT or MRI.Can utilize these images to discern the starting point of ligament and the stop to the relative articular surface thereof, be tibia in the situation of ACL.In case discerned the starting point of ligament and the estimated position of attachment region (that is, the stop of ligament), then can make to be applied to these zones or near the guiding template it.Can discern ligament starting point or stop through the profile of its uniqueness on bone surface or through ligament fibers residual fraction in the identification relevant position.
Can with the guiding template be made into size and/or conformed (that is basic coupling) for example with the adjacent patient's articular surface of tunnel location of expection.For example, can they be made into one or more skeletons and/or cartilage size and/or conformed patient, for example patient's skeleton in the outside, the load-bearing district in the intercondylar fossa and/or wherein one or more surfaces of cartilage surface.In some embodiments, can shape of template be made into and for example meet one or more projections or unique surface character or the protuberance of in the image of patient's anatomical structure, bone property vegetation or further feature, being discerned.Be used for guiding template that femur that ACL repairs or tibial tunnel place can comprise piece, adnexa or connecting device or guiding and guide pin and/or awl for reference point direction and towards and the guide hole that randomly guides and guide drilling depth.Randomly, the guiding template can be hollow or comprise opening.These guiding templates can be circular, semicircle or oval-shaped.These guiding templates can have to be held and/or one or more openings of guide needle or awl.
In one embodiment, can be placed on this guiding template on the femur or tibia entrance of expection, the top or near, place guide hole then.In case realize appropriate dissection or functional localization, then can construct the ligament tunnel.Can optimize guiding template, its shape, position and/or towards (for example, confirming before the operation) tunnel location with reflection femur and tibia desired, wherein select location, tunnel, position, towards and/or angle with reach best maybe functional effect.Other consideration when placing femur or tibial tunnel can comprise with enough distances of cortical bone so that avoid the damaged of tunnel or break.Can consider to optimize placement based on observed anatomical structure and biomechanics on the imaging test, comprise the FEM model that randomly to include the material behavior and the ligament alternate material of skeleton in consideration.
Therefore; Randomly; Can with tunnel and adjacent cortical bone and also have the distance of other articulation structure as the position of femur or tibia guiding template, shape and/or towards Consideration so that realize the optimal compromise between the possible complication of optimum ligament function and postoperative (for example tunnel breakage).
In one embodiment, can utilize imaging test to confirm the starting point and the stop of ligament.The bony landmark of identification is implemented this and is confirmed in the time of can be based on scanning (for example, CT scan or MRI scanning).Perhaps, can implement that this is definite through discerning the zone of ligament starting point for example and the ligament residual fraction in the ligament attachment region.Through confirming the starting point and the stop of ligament, can estimate and measure the graft length of expection.Can for the different attitude angle in joint (for example in various degree flexing, stretching, extension, abduction, interior receipts, to internal rotation with to external rotation) implement this measurement.
In one embodiment; Can utilize this imaging test to discern ideal graft and obtain the position; Wherein can graft be obtained the position and randomly elect as and be included in near-end and far-end sufficiently long ligament portion and bottom skeleton piece, so that satisfy as the graft length estimated based on imaging test in the early time and the demand of the randomly functional simulation of kinesiology performance (for example flexing or stretching, extension).In the situation of autograft, can utilize the additional pilot template that randomly has connecting device to obtain ligament and skeleton from the donor site.Randomly, can also utilize or design or configuration or select the guiding template to guide the scope of optional intercondylar fossa plasty.This can comprise and for example removes hyperosteogeny.
In the situation of ACL replacement, these guiding templates can be optimized the selection at femur and tibial tunnel position in this way.Even can optimize the position, tunnel for the motion and the kinematics character (comprising kinematic Simulation) of different knee attitude angle (for example joint position) and different range.Select position, suitable localized femur tunnel to guarantee maximum postoperative knee stability.
There is slight influence at the intraarticular position of tibial tunnel to the variation of graft length, but its position can utilize suitable placement, position and the shape of guiding template to optimize to prevent the intercondylar fossa bump.
And these guiding templates can comprise the optional stop of awl, for example to avoid damaging contiguous neurovascular bundle or contiguous articulation structure, comprise articular cartilage or other ligament.Randomly, these guiding templates can also comprise awl for example stop so that comprise drilling depth.
Can through use the guiding template confirm direction tibial tunnel and the femur tunnel and towards, thereby can also comprise and select best tunnel towards so that the graft length of measurement and the intraarticular length of length of tunnel and graft ligament are complementary before making operation.
In one embodiment, can guide template with tibia elects as and for example makes its opening be positioned at the anatomical structure center of ACL tibia attachment region or near thereafter.Randomly, can with the anatomical structure sign as the design of tibia guiding template, shape, towards with the position in the factor considered.These include but not limited to anterior angle, medial tibial sour jujube, posterior cruciate ligament and the anterior cruciate ligament stump of lateral meniscus.
The inward flange of anterior angle that can be through the lateral meniscus that continues prolongs straight line and locatees this position, tunnel to utilize the guiding template in the pro-back plane.Can be with this plane positioning six (6) to seven (7) mm before the inner boundary of PCL.Can just touch the outside of PCL, but can significantly not make it to depart from the position of this guiding template, shape with towards being made in size and/or making final tibial tunnel in shape and the final position of ACL graft and towards in case put in place.Similarly; Can guide template and final ligament tunnel and the final position (in case in place) of ACL graft with tibia and be designed so that proper knee is in special angle; For example during full extension, graft neither rubs and does not also clash into the inboard of lateral femur condyle or the top of intercondylar fossa.In this way, the graft that uses the exclusive template of patient to carry out pin-point accuracy is placed the problem that helps avoid bump and graft breakage subsequently.
In one embodiment, can scan to confirm the for example various values of patella tendon graft, such as maximum possible graft length before the operation of assess anatomical structure.If there be the problem of maximum graft curtailment with the ACL that is used to expect replacement, then can change and optimize tunnel location and towards, be specially from the outlet of femur or tibia, so that graft length and length of tunnel and intraarticular length are mated.
In preferred embodiments; Through measuring best graft length with the stretching, extension angle or with exclusive imaging data of patient and kinesiology data with other kinematic Simulation that simulation merges, before operation, to measure and/or to simulate optimum graft length for different flexings.Use the method; Can place at isometric graft, avoid clashing into PCL and/or avoid clashing into the optimum location that obtains out this guiding template under the optimal compromise between the condyle of femur, shape, towards and design, accessible graft length is maximized.
In operation, femur and/or tibia guiding template can comprise in one or more the operation adjusts characteristic.These adjustable features for example can make template backward or inwardly or outwards towards with one or two or millimeter spacing motion more than two, make the final motion of femur or tibial tunnel.In addition, adjustment can also realize the rotation of template in the operation, makes the final rotation of final femur or tibial tunnel.
Can utilize single template to obtain the femur tunnel.Can also utilize single template to obtain tibial tunnel.Can use either side more than a template.
Randomly, these templates can comprise connecting device, for example are used for attached other measuring device, guide wire or other operating theater instruments.Can adopt this mode to come attached or incorporate the aligning guiding device that comprises machinery, electricity or electro-optical device into.Can also use connecting device that a plurality of templates are connected on the joint side.Can also use connecting device that the one or more templates on the first joint side are connected with one or more templates on the second joint side and/or one or more templates on the first joint side and the one or more templates on the second joint side are connected to form reference.Can use connecting device to realize littler individual form element size.This can be favourable for introducing template through little inlet or miniature incision or osseous tunnel.Randomly, can or be assembled in intraarticular with these templates connections then, thereby can realize Wicresoft, comprise the arthroscope technology.
In one embodiment, can be with second joint surface (for example relative articular surface) for the first articular surface cross reference.For example, in the situation that ACL repairs, can at first use guiding template for preparing femur tunnel, thereby this guiding template helps the position, location in definite optimum femur tunnel, towards, diameter and shape.This femur guiding template can comprise down to the connector of tibia or can attached connecting device, wherein can utilize said connector or the said entrance, desirable joint of can attached connecting device confirming tibial tunnel.In this way, can anatomical environment and with the mechanical cross reference in femur tunnel construct tibial tunnel in one of them at least.Its reverse operating method is possible, at first uses thus and should guide the structure of transvers plate tibial tunnel, and this guiding template has connector or connecting device is connected to the femur tunnel of structure subsequently.Advantageously help to reduce the difficulty in the enforcement ligament repair and can improve the degree of accuracy of performing the operation in the selected clinical context with reference to constructing femur or tibial tunnel each other.In this way, these templates can be used for the initial reference first time of one or more osseous tunnels, optimize two tunnels on the relative articular surface subsequently.
In one embodiment, the template that is used for ligament repair can comprise optional flange or dilator.For example, in some embodiments, these flanges or dilator can have the function of tissue retractor.Owing to have the function of tissue retractor, the intraarticular template that is used for ligament repair can be led to entering the mouth more clearly and having improved visuality of expection position that operation gets involved for operative doctor provides.And the flange or the dilator that start from or be attached to the guiding template can also be used as organization protection's device, for example protect posterior cruciate ligament, articular cartilage or other articulation structure and joint external structure.
In one embodiment, can utilize to first or the additional pilot template of second joint guiding template or connecting device to place the ligament attachment arrangement, for example, interference screw.
If select allograft, xenograft or artificial ligament replacement; And randomly; Its size is known before operation, then can to the position in guiding template and additional tunnel, shape and towards adjusting in addition so that graft size and tunnel size coupling and make graft length and femur inner tunnel length, intraarticular length and/or tibia inner tunnel length are mated.Randomly, can be to the different attitude angle in joint, for example in various degree flexing or stretch and implement this adjustment and optimization.
Fig. 1-3 is shown in the situation of repairing anterior cruciate ligament (ACL), is used to implement the exemplary purposes of the guiding template of ligament repair.Fig. 1 illustrates the viewgraph of cross-section of femur and femur guiding template.Specifically, will guide template 1 is placed in the intercondylar fossa zone 5.At least one surface size and dimension of 10 of template 1 is made as at least one or a plurality of part that meets (that is basic coupling) intercondylar fossa 5 or femur.This meets shape and is obtained by patient's imaging research (for example CT scan or MRI scanning).Randomly, can template 1 be abutted against coaster and/or the placement of condyle of femur (not shown).Mould 1 comprises opening 20 and metal sleeve 30 randomly, the position of its split shed 20, location and towards and/or metal sleeve 30 confirm femur graft tunnels 40 the position and towards.
Fig. 2 illustrates the viewgraph of cross-section of tibia and tibia guiding template.Specifically, can use tibia template 50 confirm tibial tunnels 60 the location and towards.Definitely, can the openings 65 in the tibia mould 50 be designed to confirm tibial tunnel 160 position, angle and/or towards.This opening can comprise optional metal sleeve 68.Mate on surface basic and tibia 75, at least one surface of tibia template 50.Can make this template and tibia sour jujube 80 couplings, wherein the tibia sour jujube can help to discern the tram of mould, and in the operation intervention procedure with this template fix in position.Be noted that wherein sleeve 30 and 68 can be processed by other hard material (like pottery).Randomly, can in operation process, for example use Kirschner wire or screw that femur and/or tibia template randomly are attached to femur or tibial prosthesis surface.Randomly, this whole template can be processed by hard material (for example metal or pottery).
Fig. 3 illustrates the top view of tibial plateau.It is the same with meniscus 87 that PCL 86 is counted as.The initial position of ACL attachment region 90 is shown.The position, tunnel 92 of expection can be at the rear side a little of initial ACL attachment region 90.Can template 95 be placed on 92 tops, graft tunnel of expection.This template can comprise less times greater than the girth at the position, tunnel of expection.Randomly, this template can be used in for example attachment arrangement, connecting device, adapter or handle.
Can stencil design be become compatible with any desired surgical technic.For example, can stencil design Cheng Yudan bundle, two-beam or multi beam reconstruction technique, tibia embedding technique and other method is compatible.Being used for this type of technological device can comprise adaptation and help this type of technological special characteristic.For example, in the situation of two-beam technology, can comprise that digital octal or diplopore are to hold two bundles.
With reference to figure 4-7, illustrate and be used for the embodiment that ACL repairs or the intra-operative of replacement accurately and is simply placed the apparatus 100 in ACL tunnel at tibia.
Apparatus 100 has two parts: counterpart 110 and guiding device 120.The size of counterpart 110 is made as the end that is suitable for being placed on through coupling mechanism 140 arthroscope 130.Counterpart 110 also possibly comprise observes inlet 150, bindiny mechanism 160 and/or to site surface 170.Inlet 150 is hollow channels, and it makes arthroscope can observe operative region.Bindiny mechanism 160 is that size and dimension is made as when assembling apparatus 100 fully and the opening of guiding device 120 para-positions.Though many embodiments all are possible, shown in Fig. 6-7, bindiny mechanism integrally extends to form the tunnel through counterpart 110.
In this embodiment, be to be designed to be the surface of concave surface to site surface 170, so that surface 170 corresponding tibia surface portion pairing with this and para-positions for the specific counterpart (being preferably the zone of patient's tibia sour jujube) on tibia surface.Surface 170 individually customizes for particular patient, and is the basic concave surface pairing of bone surface or the surface that meets, and meets this bone surface.In certain embodiments, can adopt alternate manner to realize the para-position with patient's anatomical structure, for example utilize through engaging bone surface and suitably aim at the one group of pin or the notch of apparatus.
Preferably, surface 170 size be made as as far as possible little with enough big simultaneously in the zone that helps to be placed on the ACL operation so that can accurate para-position with patient's tibia so that this device locate the position of tibial tunnel exactly and be provided with its towards.
Guiding device 120 comprises that aiming is most advanced and sophisticated 180, arm 190, pin housing 200 and to site surface 210.Aiming most advanced and sophisticated 180 is that size and dimension is made as the 160 paired pins with bindiny mechanism.Preferably, in this embodiment, bindiny mechanism 160 is to closely cooperate with aiming at being connected between most advanced and sophisticated 180, so that this is connected with the accurate placement that helps provide apparatus 100.In some embodiments, these connections other mechanism that can comprise screw thread couple mechanism, be clasped part and/or be used to connect.
Site surface 210 is located at the end of pin housing 200.Surface 210 is designed to the concave surface of specific counterpart on the surface of patient's tibia, so that surface 170 meets (that is basic coupling) corresponding tibia surface portion and para-position with it with the concave surface form basically.The same with surface 170; 210 gravel size decision ground, surface be made as as far as possible little with in the zone that helps to be placed on the ACL operation simultaneously enough greatly so that can accurate para-position with patient's tibia so that this device locate the position of tibial tunnel exactly and be provided with its towards.
The size and dimension of arm 190 is made as around the intervention of tibia head and partly extends, and connects and support pin housing 200 and counterpart 110.For example in this type of operation process, can produce sizable power by the surgeon in structure (for example getting out) ACL tunnel.Therefore, arm 190 preferably is out of shape minimum material and processes by bearing this power.The suitable material of the parts of apparatus 100 comprises, for example cochrome, titanium or enough strong polymeric material.
Pin housing 200 comprises opening 220, and it is guide needle and/or awl in operation process.In some embodiments, can pin or drill bit be kept being strapped in the pin housing 200.
In the operation process, can assign to assemble this apparatus to the corresponding tables face of tibia through surface 170 and 210 para-positions.When assembling also suitably was positioned on the tibia fully, apparatus 100 provided " grasping sense " to the user.And, when assembling, aim at most advanced and sophisticated 180 and pass bindiny mechanism's 160 extensions, and aiming most advanced and sophisticated 180 rests on the position of the surface of skeleton with the exit point of qualification tibial tunnel.Near the outer surface that counterpart 110, withdraws from tibia through the head that makes tibia is configured to tibial tunnel.In this process, the aiming of ACL pin is in aiming most advanced and sophisticated 180.
Many other embodiments also are possible.For example, in another embodiment, counterpart 110 can be the part, attached or integrated with it with it of aiming most advanced and sophisticated 180, so that whole apparatus be one-piece apparatus or integrated or assemble by many devices in operation process.Though this apparatus can comprise three or three with upper-part, preferably, this apparatus have with operation in the inlet quantity used identical or than the parts that this quantity is lacked, be generally two.
With reference to figure 8-9, femur apparatus 300 is shown.In the operation identical, preferably use femur apparatus 300 to construct the tunnel in the distal portions of patient's femur with tibia apparatus 100, so that the fixing opposite end of ACL graft, as utilizing tibia apparatus 100 structure tibial tunnels.Apparatus 300 has parts: counterpart 310.The size of counterpart 310 is made as and is used for being placed on the end of arthroscope 130 through connecting mechanism 340.Counterpart 310 also comprises to be observed inlet 350, guide mechanism 360 and to site surface 370, site surface 370 is met (that is basic coupling) corresponding femoral surface (for example, skeleton and/or cartilage surface) basically.Inlet 350 is hollow channels, and it makes arthroscope can observe operative region.
Guide mechanism 360 is that size and dimension is made as and makes ACL guiding device and pin 370 through to pass the opening of counterpart 310, and is shown in figure 10.The cooperation of guiding device 360 is preferably enough tight, so that guiding device and pin 420 can pass with minimum drag, retrains any significant side direction simultaneously or rotatablely moves, and is significant outside or rotatablely move and can cause the ACL tunnel in the femur to depart from aligning direction.In other embodiments, can ACL guiding device and the pin part as the femur apparatus be comprised.
In this embodiment, be that the specific counterpart that is designed to for the condyle of femur surface is the surface of concave surface to site surface 370, so that surface 370 corresponding femoral surface with this partly cooperate and para-position.Surface 370 individually customizes for particular patient, and is the surface of the basic cooperation of bone surface, and meets this bone surface.In certain embodiments, can adopt the para-position of alternate manner realization and patient's anatomical structure, for example utilize through engaging bone surface and suitably aim at one group of pin, anchor clamps or notch of apparatus.
Preferably, surface 370 size be made as as far as possible little with enough big simultaneously in the zone that helps to be placed on the ACL operation so that can accurate para-position with patient's femur so that this device locate the position in femur ACL tunnel exactly and be provided with its towards.The suitable material of the parts of apparatus 300 comprises, for example cochrome, titanium or enough strong polymeric material.
With reference to figure 10-11, in operation process, apparatus 310 is placed on the arthroscope 130, and will places against the corresponding surface of condyle of femur 380 site surface 370.When assembling also suitably was positioned on the femur, apparatus 300 provided closely and firm sense to the user.The outer surface that withdraws from outlet 390 place's femurs through the distal portion that makes femur constructs the femur tunnel 400 with opening 410.
Many variations based on embodiment characteristic described herein also are possible.For example, similar with tibia apparatus 100 in certain embodiments, the femur apparatus can comprise having a plurality of (two or more) many designs to site surface.Perhaps, the tibia apparatus can have single to site surface.But; Preferably; The femur instrumentation single to site surface so that comparatively simple apparatus is provided; It utilizes the spine on the condyle of femur that firm cooperation is provided, and the tibia apparatus comprise a plurality of to site surface so that on the common more smooth relatively and more uncomplicated geometry more firm cooperation is being provided on the tibial plateau.In addition, the same with the tibia apparatus, this femur apparatus can comprise three or three with upper-part, but the quantity of the parts that preferably had is no more than the quantity of the inlet that relates in the operation.
In one embodiment, can comprise counterpart with apparatus 100 similar apparatuses, this counterpart comprise in addition along with tibia one side on guiding device identical the axle aligned tunnel-shaped opening.Thus, with the most advanced and sophisticated place of the pin aiming aiming on tibial plateau, but along aiming axis this pin that moves, and in motion once, pass the opening in guiding device opening and the counterpart simultaneously.This type of embodiment can be used with tibia and femur, and in knee or other joint, implements embodiment with Dan Shu and multi beam and use.In addition, this type of embodiment can comprise two non-attached guiding devices, or as alternative, can comprise the arm that connects two guiding devices with in operation process, increase the pin opening towards extra para-position and increase extra stability.
In another embodiment, can use single instrument configurations femur and tibial tunnel, this single apparatus provides the aligning of tibia and femur tunnel location simultaneously, so that can use along these two tunnels of cutting configuration of common axle.Preferably, in this embodiment and other embodiment, with reduce and/or eliminates the tunnel opening that leads to articular cavity the degree of eccentricity mode and towards these tunnels of structure, so that this tunnel is a circle or round in shape.Wherein, this helps to reduce the wearing and tearing of ACL graft at the edge of opening place, and is regarded as most of doctor's preferred geometry of implementing this type of operation.
The embodiment that preceding text combine Fig. 4-11 to discuss comprises single bundle technology.A potential defect of single bundle technology is that operation possibly can't be duplicated patient's natural anatomic structure.At first, this operation can not duplicated the previous existing ACL that is formed by two ligament bundles (preceding inboard (AM) and the outside, back (PL) ligament bundle), and these two ligament bundles are attached at position slightly different on tibia and the femur.In addition, single Shu Fangfa possibly cause the tunnel mispairing.Tibia AM position is not connected to femur AM position and tibia PL position is connected to femur PL position, but it possibly produce certain mispairing because of tibia PL position (B) being connected to femur AM position (A) or tibia PL position (B) being connected to high AM position (height).
Therefore, in some embodiments, this not matching is able to avoid, because can confirm the exact position that patient's AM is connected with PL, and it merged in the apparatus.This type of embodiment (comprising and be not limited to combine those that Fig. 4-11 discusses) is through more closely improving single bundle ACL reconstruction technique with the position of the natural A CL that is rebuilding towards coupling.
In the ACL operation, can also use other embodiment to adopt the two-beam technology; It can closely duplicate patient's natural anatomic structure; Mode is to hold the ACL bundle of two reconstructions; And provide than the doctor and utilize existing method and apparatus to realize, natural aim at and of restrainting with patient's natural A CL AM and PL towards more approaching coupling.Hereinafter with reference Figure 12-15 illustrates this type of embodiment.
In Figure 12-13, be illustrated in the femur apparatus 500 that uses in the two-beam ACL reconstruction operations at the far-end of femur 510.Apparatus 500 is similar with the apparatus 300 that preceding text are discussed.What here, apparatus 500 comprised the location and aimed at apparatus 500 meets the exclusive surface of patient 520.Apparatus 500 also comprises two openings 530 and 540, and it is used to be configured to the two personal share osseous tunnels 550 and 560 of the fixing two-beam ACL that rebuilds.In Figure 12, use pin 570 (or other device that is fit to, like awl) structure first tunnel 550.Use pin 580 structures second tunnel 560, shown in figure 13.
With reference to figure 14-15, can combine femur apparatus 500 (or separating with it) to use tibia apparatus 600 with two tibial tunnels of structure in two-beam ACL reconstruction operations process.(perhaps, in alternative embodiment, can utilize tibial tunnel of two personal share osseous tunnels structures, comprise two ACL bundles) as long as the size of individual tunnel suitably is made as.Apparatus 600 has the similar 26S Proteasome Structure and Function of the tibia apparatus discussed with preceding text 100, but except having the tip 610 to site surface 640, apparatus 600 also has two guiding parts 645 and 650.Each guiding part has unique in site surface 660 and 670 respectively, and aiming tip 680 and 690.In addition, most advanced and sophisticated 610 comprise two openings 620 and 630, and it is used at two tibial tunnels of operation process structure.
In the operation process, randomly be placed in the opening 620 first guiding part 645 is attached to most advanced and sophisticated 610 through aiming at most advanced and sophisticated 680.With the patient exclusive to site surface 660 and 700 and the corresponding tables of tibia in the face of the position, as shown in the figure.Can based on imaging data adjust apparatus 600 length, shape and/or towards, or can be in operation adjustment devices 600 length, shape and/or towards so that can guiding part 645 and 650 be aimed at opening 620 and 630 respectively simultaneously.Use pin 710 (or other device that is fit to, like awl) structure first tunnel then.Then, remove first guiding part 640, and place opening 630 second guiding part 650 is attached to most advanced and sophisticated 610 through aiming at most advanced and sophisticated 690.With the patient exclusive to site surface 670 and 640 and the corresponding tables of tibia in the face of the position, as shown in the figure.Use pin 720 structures second tunnel then.Perhaps, femur apparatus 500 and tibia instrument tip 600 wherein any or the two can respectively comprise single opening constructing a tunnel, and can comprise the second paired parts, its have different towards opening to construct second tunnel.In another other embodiment, on the contrary can utilize two personal share osseous tunnels construct a tibial tunnel or.
With reference to Figure 16-17, the alternative embodiment that is used to implement the femur apparatus 700 that two-beam ACL rebuilds is shown.Apparatus 700 is realized function with the apparatus 500 similar modes with the preceding text argumentation.But apparatus 700 also comprises bigger hole section 710, and it provides the expanding reach 720 in tunnel 730, and this expanding reach 720 has than the bigger diameter of other part in tunnel 730 to hold bigger ACL graft.In this embodiment, randomly, can go extra skeleton to form bigger hole section 710 through after the narrower tunnel 720 of first formation, boring.
In other embodiments; Can use the pin structure tunnel that is placed in first tunnel; Come for constituting extra reference and stability at the same section (for example, the first and second femur tunnels) of skeleton or the follow-up tunnel boring on the different piece (for example other combination in first tibial tunnel and the first femur tunnel, the second femur tunnel and first tibial tunnel, first and second tibial tunnels and the first and/or second femur tunnel or tunnel) at skeleton.
Though the embodiment that preceding text combine Figure 12-15 to describe is used the natural stop position of AM and PL ACL bundle; But other embodiment also is possible; Comprise can be at ACL operation process middle part bit position and location, in the ACL operation process adjustment part bit position and location, before operation, automatically confirm anatomical structure facies posterior hepatis bit position and location or confirm that before operation attachment position optimum or that more optimize (especially suffers from joint disease the patient to produce the kinesiology performance and/or the stability that have better off now than the patient; As and be not limited to, in the arthritis of existing ACL and/or related tissue or the situation of degeneration) embodiment.
Preceding in operation (comprising the operation of ACL and other type), can remove the impaired ligament or the residual fraction of other soft tissue.But in the situation of ACL and other operation, many doctors would rather keep this tissue and search and the localized tunnel opening with help.In this type of situation, can design this apparatus to avoid the residual fraction of this tissue, mode is that customization is directed against this patient's apparatus or comprises this category feature in the standard design.
In multiple embodiments; Can be with meeting (promptly; Basic coupling) the para-position surface design on the corresponding surface of patient's anatomical structure becomes the surface of the combination of basic and skeleton (comprise and be not limited to cortical bone and/or subchondral bone), cartilage, other soft tissue or tissue to mate.
In another embodiment, can also be used for the imaging research that designs instrumentation and produce and come planning surgery.For example, can select graft, confirm the length of graft, confirm the position of graft, can confirm the tunnel towards, size and location.And, can operation and device design be become to comprise that the doctor imports so that explain the patient's and/or the particular case of performing the operation and the doctor preference to technological and device characteristic.In addition, instrumentation can be designed so that the doctor can implement adjustment in operation process.Can also control the multiple geometric characteristic of these apparatuses, like the angle between the tunnel and spacing to guarantee guaranteeing between each tunnel that enough bone storages are arranged.The variation of these operations can also comprise through difference inlet deployment instrument and/or through the different available outlet structure tunnels of going into.
Can use patient's the existing anatomical structure sign and/or the combination of sign to confirm the AM of two-beam ACL graft and the position placement of PL part.For example; Use CT scan to search the bone ridge between patient's the attachment area of natural A M and PL part of ACL, and can with its with for example take from one of them or the two one or more average departure values and make up and use from the spine of coaster ditch to AM and PL attachment area.
In another embodiment, can be the position para-position of robot to help in the operation process with the arm that these apparatuses are placed on robot, this can reduce the time of the operation that robot assists widely.
1.3 PCL treatment
Similar with the ACL reparation, the treatment of posterior cruciate ligament (PCL) damage is in sustainable development.
At present, multiple factor is depended in the selection of therapeutic scheme.In some embodiments, select best option to include patient and impairment factor in consideration simultaneously.Though the position of associated injury, time, the order of severity and scope possibly be important prognosis factors, patient's age, occupation, health condition, sex and be desirably in and play a part no less important in the decision making process.At present, many acute simple local PCL damages (I level and II level) can not cause that operation gets involved.The secondary restraint structure of the possible optimum reason of these damages and PCL and the residue integrity of multiple part are relevant.And, shown that these parts tear and have the strong tendentiousness that is tending towards healing.If these damages are suitably treated, chronic remaining back then possibly take place relax, thereby cause ligament in elongated portion, to heal.Therefore, the initial treatment of local PCL damage can comprise protected load-bearing, uses knee holder with padlock hinge or fixed mount and/or musculus quadriceps and triceps muscle rehabilitation programme to offset the subluxation of tibia rear side.The non-operative treatment of tearing (III level) merely fully of PCL does not then have high success rate.Regrettably, wherein many not recoveries from illness of these damages, and as time passes, these patients possibly develop into the symptom of the shear stress of the articular cartilage (the especially articular cartilage in inboard and kneecap thigh gap) that is secondary to increase.Therefore, if although farthest carry out naturopathy, these patients still continue to have symptom, then operation are often selected in these patients' suggestion.
PCL reconstruction technique sustainable development at present, and usually comprise: 1. the condition of illness relevant discerned with treatment; 2. the risk with the neural blood vessel damage drops to minimum; 3. select, place, suitably tensioning and firmly fix enough strong graft; And 4. prepare for long-term rehabilitation.
1.3.1 repair and rebuild
Repair the decision-making of still rebuilding the ligament of tearing and depend on multiple factor.MRI in definite which structure can repair and which can rebuild helpful especially.In general, repair not as rebuild firmly, and usually after the Design Technology modification of therapeutic scheme reflected this difference.Regrettably, the same with the situation of ACL damage, the elementary reparation that the PCL body is torn is success never.PCL bone or the fracture of ligament stop are the situation of exception, wherein repair these damages and obtain gratifying result usually.Can adopt multiple operation method according to other relevant ligament and meniscus injury, this possibly need treatment and comprise back inboard, the outside, back and rear side method and all arthroscope technology to knee.In addition, described the various fixed method, and these fixing meanss are decided because of the osteocomma size.The osteocomma of tearing for big can use the AO screw, and can utilize Kirschner wire or tension band or stablize less osteocomma through the stitching thread reparation of passing boring.
1.3.2 the technology of rebuilding
Repair or rebuild for PCL, developed and multiple diverse ways.Recovery most probable after PCL rebuilds that present most of surgeon admits normal anatomical structure obtains conforming result.Exist multiple change because of, comprise that graft selection, fixed type, tunnel place and inlay and the tibial tunnel technology.Two adopted reconstruction techniques the most normal are through tibial tunnel and tibia embedding technique.And some researchs have shown that the two-beam structure can have the biokinetic killer opportunity at reproducing in vitro PCL; But clinical research is not proved conclusively this technological result as yet than making moderate progress on intravital single Shu Chongjian.
1.3.3 graft is selected and fixing means
Existing multiple tissue is used for knee and rebuilds.Autologous tissue comprises patella, rope tendon or quadriceps femoris tendon.Heel string, patella tendon and tibialis anterior tendon are the most frequently used allograft's tissues.A plurality of researchs confirm the situation as the autotransplantation fabric texture through arthroscope and tectology method; Allograft's tendon of transplanting reproduces blood vessel; The experience cell is bred and is reached the period of maturation, though for allograft's tissue, this process possibly spend the longer time.Heel string allograft usually is first-selected, because its tensile strength is high, operating time is shorter, transmit easily and lack the donor site condition of illness in the impaired knee.Additional advantage comprises, its unusual size and length and bone attachment region at one end, thus have multiformity when selecting relatively with other graft.Also there is the various fixed method, comprises metal and bioelectric interface screw, fasteners, cortex screw and soft tissue packing ring or nail.When in most applications, soft tissue being fixed to skeleton, first-selection is to use screw and soft tissue packing ring, is the most stable fixing because shown this.
1.3.4 the tunnel is placed and the graft tensioning
Biomechanics Research is supported in and rebuilds ventrolateral tract when implementing list bundle technology.In the anatomical structure attachment region, place the femur tunnel forward and show to recover that normal knee is lax to be superior to isometric graft and to place.Similar with the ACL operation, placing osseous tunnel is important for the success of performing the operation.Variation during tibial tunnel is placed can influence the variation of the degree of graft performance less than the placement of femur tunnel.And wherein tensioning possibly have appreciable impact to the knee mechanical property with the position of fixing non-isometric graft.
1.3.5 single Shu Chongjian
Single bundle technology has developed into the reconstruction ventrolateral tract, because compare with the back medial cord, its size is bigger and the biodynamics characteristic is bigger.When attempting that graft is placed on the anatomical position of natural ventrolateral tract, can utilize single tibia and femur tunnel.Reproducing normal anatomical structure can be ideal position, wherein in the dissection ventrolateral tract attachment region of femur, places the tunnel forward.Utilize the method together with under knee flexion 90 degree with the tension force of pulling force tensioning graft forward, it is reported to have produced good result.
The placement of relevant tibial tunnel shows, from the anterointernal tunnel bending that can produce non-expectation through the tibia drilling technique of tibia.Having developed multiple technologies uses tibia embedding technique that tunnel, the outside behind the tibia and hereinafter describe to limit the angle of this graft.
1.3.6 two-beam is rebuild
For reproducing the sophisticated functions anatomical structure of PCL more accurately, attempt to have introduced the two-beam reconstruction technique.Show that according to human dissection two-beam PCL rebuilds the biodynamics performance that can closer on the entire motion scope, recover normal knee.Though the biodynamics performance of knee was recovered at paramount knee flexion angle during traditional single Shu Chongjian pressed, when knee possibly exist remnants to relax during near full extension.Biodynamics research shows that the tibia retrodisplacement when medial cord has reduced knee flexion and stretching, extension after increasing indicates this bundle to play an important role in the overall process of knee flexion.Though technical challenging, two-beam is rebuild the first-selected surgical technic that has become chronic PCL defective, because the recovery of the normal knee dynamic performance of its improvement.
1.3.7 tibia is inlayed
Initial introducing tibia embedding technique is the potential abrasive problem for fear of bone bolt passage that passes long tibial tunnel and tibia rear side exit point.It also can help the neuroprotective blood vessel structure.Adopting the rear side method can simplify rear side to PCL tibia stop exposes.This technology is the most common to be to be used with patella tendon autograft, still it is said recently and uses with two-beam heel string allograft.
1.3.8 combination damage
Combination PCL (posterolateral stucture) PLS damage is one of plastic surgeon's the most complicated knee damage mode that possibly run into.When PCL and PLS all rupture, the knee flexion place of different angles all possibly exist bigger retrodisplacement, to external rotation and in open mouth.This combination causes complicated surgical selection, and this usually requires operative doctor to have more than a kind of operation plan.Imagined many reconstruction techniques, comprise arcuate popliteal ligament move preceding, biceps tendon is fixed and utilize allograft or the diseased ligament of autotransplantation fabric texture is rebuild.Unsteady chronic case shows the redundant and undue scarring of LCL rear side tissue, the feasible ad hoc structure difficult and complicated of knowing other popliteal flesh outside the back.Therefore, the time of the operative treatment of impaired PLS is vital, and acute reparation obtains more gratifying result than the reconstruction of chronic injury always.The chronic PCL damage that comprises PLS has more challenge in operation.If the PLS damage is left in the basket or does not find, then repair or rebuild other ligament and possibly have the chronic material risk that stretches repeatedly and fail because of rebuilding.The operative treatment of PLS damage concentrates on and rebuilds but not the reparation of defect sturcture in chronic injury.It is first-selected that the front side of calf ligament rebuilds, and if necessary, selects LCL.If turn over malalignment or lateral thrust in existing, then can implement proximal tibial osteotomy and proofread and correct this ligament.Implement osteotomy though can combine PLS to rebuild, because the symptom that only osteotomy just can reduction of patient, can be with the operation phase in, thus avoid further operation intervention.
1.3.9 complication
Failing to discern with the relevant ligament injury of treatment suitably is the FAQs that runs into during PCL performs the operation.Equal scrutiny in preceding and the operating room of performing the operation notes carrying out MRI and arthroscope is observed, the identification that can improve all damaged structure.For many patients, successful result depends on the reparation and/or the reconstruction of all tearing configurations.Perhaps in addition, neural damage possibly cause complication to patient's tremulous pulse, vein or tibia in the operation process.Damage maybe guid needle through or take place during reaming.In embodiments more described herein, PCL tibia guiding device is designed has the protection aiming arm to reduce the probability of this type of damage of intra-operative.With hand operated to the boring of the rear side cortex of tibial tunnel for can being important safety measure through the tibial tunnel technology.The inboard safe otch in back is another strategy that can reduce this risk.Through eliminating through tibial tunnel, the tibia embedding technique is another approach of restriction neural blood vessel damage.
1.4 be used for the exclusive tool and method of patient of PCL treatment
All embodiments of in the context that ACL repairs, describing also can be applied to PCL and repair, and repair other ligament or tendon.
Repair for PCL, can come the design guide template to single bundle and two-beam surgical technic.In the situation of single art technology in a helpless situation; Can construct the guiding template; Wherein the position of this template, towards and/or shape or the reciprocal reference point or the guiding device that are used for operating theater instruments help structure femur tunnel in the position of expectation, for example in the position of the dissection starting point of ligament.Perhaps, can and be placed in to dissect in the attachment region with this template and any reciprocal reference point or guiding device or connecting device design and place the femur tunnel forward.Randomly, place the femur tunnel more forward and can place that to recover normal knee better lax than isometric graft.Can guide template with these and be designed to not only when the knee extension but also also realize optimum tension during in knee flexion, especially when 90 degree knee flexion.Therefore, can be based on scanning through discerning starting point and the stop that remaining fibre bundle or identification bottom anatomic landmark come identification PCL before operation.Therefore can when stretching, confirm the distance between starting point and the stop, and can simulate the distance (for example, using the exclusive model of patient in patient joint to simulate) between starting point and the stop for different range of flexion or other joint position with virtual mode.Can implement kinesiology modeling and simulation and finite element modeling so that further optimize, repair to ACL as preceding text and summarized, wherein use similar principle.Can optimize then that femur and tibial tunnel are placed and towards so that realize isometric or place near isometric ligament.The middle adjustment that undergos surgery as described in the embodiment of front is feasible.
Can also use the two-beam reconstruction technique in femur and tibial side while design guide template.In the situation of two-beam reconstruction technique; Femur or tibia template can comprise or merge connector maybe can have can be attached connecting device; So that can construct the femur tunnel and, maybe can construct tibial tunnel and with itself and femur tunnel cross reference with itself and tibial tunnel cross reference.
As described to ACL, these templates can comprise the stop of awl and Counterboring apparatus or other operating theater instruments, for example with protection tremulous pulse neurovascular structure.These templates can comprise that dilator or flange are to be used as tissue retractor and organization protection's device.
As what before pointed out, the guiding template can be applicable to the ligament or the tendon repair of any kind, not only can be applicable to ACL and PCL reparation, and can in operation, provide renewable and simply expect the location in attachment area or tunnel.Can to joint anatomical structure and biodynamics situation individually customize and optimize the guiding template size, shape, towards and the position; And the shape that not only can incorporate the corresponding joint shape on the anatomical structure that meets the patient into; (for example separate hatching line, anatomical planes, biomechanics line or biodynamics plane but also can comprise that the patient is exclusive; On template, mark), and device or the anchor or the apparatus of that will implant or that will during implanting, use or the some or all shapes that will during the surgical repair that ligament or tendon are torn, use.Except dissecting the optimization of placing; Technology described herein can also realize kinesiology modeling and simulation, finite element modeling, and all these randomly combine with patient's imaging data and can realize in the operation of graft function assessment and carry out relevant adjustment.
The alternative design of Figure 18 and 19 diagram cutting cubes 820, it provides additional structure 860, and ligamentum cruciatum avoids being cut in the operation process for example to protect.These additional structures can adopt the guiding device 860 (shown in figure 19) of expection or the form of other structure that is fit to.Shown in figure 18, device can comprise interior mould 810, and it is configured to upper surface and forms protruding dome 850, and protruding dome 850 connects with recess 852 on the inner surface that is located at cutting cube 820.
In alternative embodiment, employed multiple parts can insert with other device that enters the mouth via endoscope, arthroscope or provide passage to get into the joint enough for a short time.In addition, in some embodiments, can be with a plurality of segmentations or assembly, the form that is preferably subsection or widget designs these instruments and device, is assembled in the surgery location place in the human body in the time of like this can be in being inserted into human body.This type of device can have locking or other mechanism (for example machinery or magnetic couple), so that this device can be assembled.
In another embodiment, can in operation process, send the template that is used to place the far-end tunnel through the near-end tunnel of having constructed.For example, if constructed tibial tunnel, then can place template with structure femur tunnel through this tibial tunnel.Another instance and for example, opposite situation also is possible.If constructed the femur tunnel, then can place template through this femur tunnel with the structure tibial tunnel.Can be in the joint space outwards motion or from joint space outside, inwardly move and place first tunnel of beginning towards relative another articular surface.
This notion not only can be applicable to ACL and PCL, also can be applicable to the ligament repair of any kind.Can insert instrument and device or segmentation and assembly by the osseous tunnel in extending to the joint.
This type of device can preferably be made up of some widgets, and these widgets are through the distal femoral articular surface was sent and be assembled in to inlet or otch or femoral tunnel position.Multiple embodiments can comprise multi-part device through assembling and the part para-position (surface that for example, has basic coupling) of an articular surface, through the part para-position of assembling and an articular surface and be connected to the multicompartment device in the relative tunnel of the articular surface of this device para-position, through the multicompartment device of assembling and the equal para-position of part of two articular surfaces and through the equal para-position of part of assembling and two articular surfaces and be connected to the multicompartment device in the tunnel relative with the articular surface of this device para-position.Many other embodiments also are possible.
Its template or parts can also be deployable designs.Nitinol or other " memory-type " material are randomly adopted in this type of deployable design.Preferably, before inserting and when inserting, this template or instrument or device and parts can be very little on shape or cross section.In case insert, this template or instrument or device and parts can launch.This expansion can be initiatively, for example in the situation of Nitinol, or passive, for example through helping to launch the auxiliary device of this device or instrument.And, can for example use one or more surfaces and the patient coupling of imaging data with this device.Perhaps, can select predefined size or shape or surface to connect based on imaging data with the optimum of realization in operation with patient's articular surface.
2. other application of the exclusive instrument of patient, apparatus and method
In some embodiments, these method and apparatus described herein can be used for the location and obtain graft semitendinosus m. and/or gracilis autograft (rope tendon).The position of this type of graft is difficult to accurately locate, and this difficulty possibly make some surgeon fully avoid operation.This position is generally apart from the about 5cm of tibial plateau front side protuberance.Based on the operation device of patient's proprietary information the exact position of this type of graft can be provided, and improve ability and the reliability that improves operation itself and the result of associated patient that the surgeon implements this type of operation.
In some embodiments, can adopt device and technology to confirm the size of the graft that ligament repair is required.For example, can adopt patient's proprietary information to confirm natural ligamentum cruciatum or the size of other ligament in the knee.Even tear or be stretched, still can or partially or even wholly utilize the auxiliary size of automated software through manual type by this ligament of joint space, skeletal structure and ligament estimation itself.For this purpose, can adopt kinematic Simulation or it is combined with imaging data.Different flexings and the graft length that stretches angle can be for example confirmed in these simulations.And, can confirm and optimize different stops and starting point based on available graft and graft length.
In some embodiments, can adopt apparatus and method to observe the size of rope tendon tissue of the graft of the reparation that can be used as ACL, PCL or other ligament.This type of embodiment partly has superiority, because they help to guarantee the size of graft, and for example length and/or diameter.
In some embodiments, can place and/or use exclusive operating theater instruments of patient or the exclusive device of other patient through robot device or other similar device.Can the exclusive operating theater instruments of patient be attached to the limb or the articular surface of the anatomical structure that meets the patient basically.Can the exclusive operating theater instruments of patient be connected to robot through for example machinery, magnetic, electronics or wireless mode then.The position of the exclusive operating theater instruments of patient can help with fast with have mode cross reference limbs or joint or other patient's geometry and the robot of time efficiency or be attached to robot or by the position of any operating theater instruments of robot manipulation.Can also use the anatomical structure of the exclusive operating theater instruments cross reference of patient operation guiding system.In this way, can quicken widely, thereby shorten the required time of operation robot or navigation system step consuming time with respect to patient's anatomical structure para-position.
In some embodiments, can pick off be placed on surgical guide device and other apparatus, for example to help correctly with guiding device and articular surface para-position or in others assisting operation step.Similarly, can pick off and endoscope or arthroscope inlet be used in combination with the placement that relevant surgical guide device or other device are provided and the information of function.Pick off can be based on light or radio frequency.Pick off can be wireless.Pick off can also comprise pressure probe and can carry out pressure measxurement.
In some embodiments, the surgical guide device can comprise the placement of sighting device or assistance device or other device of other operating procedure.This type of device can for example be assisted ACL or the far-end of PCL reconstruction and the placement in near-end tunnel.
In some embodiments, the exclusive template of patient can be mated or para-position bone characteristics or labelling, and for example kneed intercondylar fossa or hyperosteogeny assist correctly to place and aim at.
In some embodiments, can locate the direction vector of one or more osseous tunnels so that help the correct aligning and the placement in tunnel.For example, in ACL rebuilds, can use inboard method that tibial tunnel is aimed at femur, wherein tibial tunnel aimed at the lateral direction component with respect to intercondylar fossa.This can improve resistance and/or rotational stabilization.This can also realize round hole and littler angle in the tunnel opening place on the joint.Similarly, in another embodiment, the vector that can select the tunnel is with in the structure periphery navigation, for example the deformity in the skeleton, the device implanted during from the implant of the metalwork of previous operation, arthroplasty, operation on ligament.
In some embodiments, the exclusive device of patient is placed the guid needle that passes through with awl in the protection operation process backward.
In some embodiments, can be through making joint flexing and stretching, extension and guaranteeing template para-position and aim at the aligning of establishing the tunnel when flexing, stretching, extension and/or the centre position.This para-position and/or aligning can carry out on an articular surface or carry out with reference to two articular surfaces.
In some embodiments, the instrumentation that is used to place can be virtual.For example, in this type of embodiment, in operation process, can adopt alternate manner to be placed on operative site from the video feed that is inserted into the endoscope in the operative region or video camera or other sensor device.In using the situation of endoscope, handle video feed so that the video information of normal observation to be provided to the surgeon, and the imaging data (like CT or MRI data) that also combines in addition to make up before the operation is handled this video feed.In operation process, computer or similar device are handled this information, and will be from the view of endoscope and imaging data comparison with the correct placement of confirming associated tunnel or otherwise guide other and additional step.For example, in some embodiments, can the display of visually sign, to show the correct placement of tunnel and/or apparatus.In other embodiments, can for example comprise other pick off on cutting or the boring bar tool, so as with virtual mode confirm and/or the checking tunnel correctly towards.
Discuss in more detail in the paragraph hereinafter broadly and relevant other principle and the notion of the exclusive operation device of patient and method (comprise and be not limited to the operation tool that the preceding text description is used for ligament repair).
3. the assessment of the exclusive anatomical structure of patient
3.1 imaging technique
Can understand as those skilled in the art, adopt the enforcement of the embodiment of imaging technique preferably to adopt x radial imaging and processing, x beam layer in this area to form images, comprise the conventional method of ultrasound wave, computer tomography (CT scan), nuclear magnetic resonance (MRI), light coherence tomography, single photon emission tomography (SPECT) and the PET (PET) of a-scan, B-scan and C-scan.But other imaging technique also is possible.Imaging technique explains fully that in document this paper need not to describe.Write referring to for example " X-Ray Structure Determination:A Practical Guide, second edition " Stout and Jensen, 1989, John Wiley & Sons, publisher; " Body CT:A Practical Approach " Slone writes, and 1999, McGraw-Hill publisher; " X-ray Diagnosis:A Physician ' s Approach " Lam writes 1998 Springer-Verlag, publisher; And " Dental Radiology:Understanding the X-Ray Image " Laetitia Brocklebank writes 1997, Oxford University Press publisher.See " The Essential Physics of Medical Imaging (2nd Ed.) " again, Jerrold T.Bushberg etc.
Can understand as those skilled in the art; Be suitable for measuring ill cartilage or cartilage disappearance the zone thickness and/or curvature (for example; The curvature of cartilage and/or skeleton) or the imaging technique of size comprise x ray, nuclear magnetic resonance (MRI), computer tomography scanning (CT is also referred to as axial tomography of computer or CAT), light coherence tomography, ultrasound imaging techniques and the photoimaging technology used.(see the open WO 02/22014 of international monopoly of the Alexander that announced on March 21st, 2002 etc. again; The U.S. Patent number 6,373,250 of the Tsoref that on April 16th, 2002 announced etc.; And (2002) Radiology 222:430-436 such as Vandeberg).Can use any route of administration, for example vein, intraarticular and/or other route of administration are so that adopt contrast or other reinforcing agent.
3.2 measure in the operation
As the substituting or replenishing of above-mentioned non-invasive imaging technology, can in arthroscope operation or arthrotomy operation process, obtain the measured value of curvature of measured value and/or cartilage or skeleton of dimensional measurements, the cartilage thickness in anatomical regions (for example ill cartilage zone or cartilage disappearance zone) in the art.In the operation measured value can but not necessarily comprise the actual contact with one or more zones of articular surface.
The device that is suitable for obtaining measured value in the operation of cartilage or skeleton or other articulation structure and generates this surperficial topography includes but not limited to keratoscope (Placido disk), photo measure instrument and device, photoimaging instrument and device and laser interferometer and/or deformable material or device.(referring to, the U.S. Patent number 6,382,028 of the Wooh that for example announced on May 7th, 2002 etc.; The U.S. Patent number 6,057,927 of the Levesque that on May 2nd, 2000 announced etc.; The U.S. Patent number 5,523,843 of the Yamane that announced in 1996 7 about 4 days etc.; The U.S. Patent number 5,847,804 of the Sarver of December in 1998 announcement on the 8th etc.; And the U.S. Patent number 5,684,562 of the Fujieda of announcement on November 4th, 1997).
4. exclusive Design of device of patient and manufacturing
Can adopt 2D and 3D form to show ligament, meniscus and other articulation structure.The description of relevant kinds of surface parametric representation, referring to for example Foley, J.D. etc. " Computer Graphics:Principles and Practice in C "; Addison-Wesley, second edition, 1995).
Can the 2-D or the 3-D of cartilage and/or subchondral bone and other anatomical structure and articular repair system be represented to merge in the common coordinate.Can articular repair system be placed on (comprising operation tool and apparatus, mould, original position repair system and/or other parts) implant site of expectation then.In 2-D or 3-D image, play up the expression of cartilage, subchondral bone, ligament, meniscus and other anatomical structure and articular repair system, for example application programming interfaces (API) OpenGL (the java standard library of the senior 3D graphing capability of standard of SGI company limited exploitation; Can be used as video card based on PC (for example from Www.nvidia.comNVIDIA video card acquisition) or 3Dlabs product (from Www.3dlabs.com) the part of the driver that obtains of a part obtain perhaps a part of obtainable as the systems soft ware of Unix work station) or DirectX
Figure BPA00001479321300392
(based on Microsoft Windows
Figure BPA00001479321300393
The multimedia API of PC system; Can from Www.microsoft.comObtain).Can play up or show 2-D or 3-D image; With interactive mode or nonreciprocal mode, in real time or in non real-time (through for example rotation or motion) show cartilage, subchondral bone, ligament, meniscus or other anatomical object and articular repair system from different angles.
5. the exclusive operation tool of other patient
Can use the device of the outer surface that is applied to articular cartilage or skeleton (comprising subchondral bone) to provide the operation of using the exclusive implant of patient and operation and other device and operation to assist, so that the aligning in coupling articular repair system and acceptor site or joint.This device can be circular, avette, oval, arc or irregularly shaped in shape.Can select or adjust shape with the zone of coupling or closed ill cartilage or than big slightly zone, the zone of ill cartilage or than the remarkable big zone of ill cartilage.Whole articular surface or load-bearing surface can be contained in this zone.When imagination replacement major part or whole articular surface, this type of device is normally preferred.
The machinery assistance (for example, operation tool) that undergos surgery be can use, gel, mould, plastics or metal for example used.Can obtain measured value in one or more electronic images or the operation, so that the object coordinate that limits joint and/or bone surface and shape to be provided.The coordinate (for example using the CAD/CAM technology) that can utilize these objects is to the device configuration; So that meet the anatomical structure in (that is coupling or para-position basically) patient joint or as alternative to select having the device of making in advance usually that well connects with the anatomical structure in patient joint.This device can have the surface and the shape of basic coupling all or part articular cartilage, subchondral bone and/or other bone surface and shape.This device can comprise and be not limited to, and one or more cutting planes, hole, groove and/or hole are to hold operating theater instruments (like awl, reamer, scraper, Kirschner wire, screw and saw).
This mould can be designed to be retained on the extra-regional skeleton or cartilage of treating operation (for example cutting, boring) or otherwise operation.In this way, can use identical mould to implement a plurality of operating procedures.For example, in knee, can be against the partially stabilized mould of intercondylar fossa, these parts can be elected as outside the zone that whole knee endoprosthesis excision or other operation will remove.Can for example utilize pin or awl and/or other device that this mould is attached to the bottom bone.
In additional embodiment, this mould can be retained on the articular cartilage.On the structure outside the articular surface that this mould can be retained on the subchondral bone or joint space is interior or on the structure outside the joint space.If mould is designed to be retained on the cartilage, then can use the imaging test that shows articular cartilage in one embodiment.This can comprise ultrasound wave for example, spiral CT arthrography, for example use cartilage to show the MRI or the MRI arthrography of pulse train.In another embodiment, can use the imaging test (for example CT or spiral CT) that shows subchondral bone, and can the standard cartilage thickness be added in the scanning.Can use and for example dissect any method that known or development in the future in comparable data storehouse, age, sex and race's coupling, age adjustment and this area is used to obtain the estimation of cartilage thickness and obtain the standard cartilage thickness.In some embodiments, the standard cartilage thickness can be uniformly on one or more articular surfaces, or it can change on articular surface.
Can mould be adapted to basically and be retained on the subchondral bone.In this situation, remaining cartilage possibly constitute certain deviation and inaccurate result, thereby causes the finally inaccurate of surgical cut, boring etc.In one embodiment, in the first step, in the zone that mould is designed to contact skeleton and expose subchondral bone, remove remaining cartilage.In second step, then mould is placed on this subchondral bone.
In the arthritic late situation, possibly cause significant joint deformity.It is smooth that articular surface possibly become.Possibly exist cyst to form or hyperosteogeny formation.Possibly on articular surface, form " tram rail " shape structure.In some embodiments, can before generating mould, remove hyperosteogeny or other deformity by computer software.This software can be automatic, semi-automatic or be manually imported sham operated by the user and remove hyperosteogeny or other deformity, and the net shape of prediction joint and relevant surfaces.Can design mould based on predicted shape then.In the operation, can also before placing mould and implementing operation, randomly remove these hyperosteogenys or other deformity then.Perhaps, can mould be designed to avoid this type of deformity.For example, this mould can be only with articular surface on not influenced by arthritis or point or articular surface that arthritis is related are not contacted by the point that arthritis influences or arthritis is related outward.This mould can be retained on the articular surface or the outer point or little surface more than three or three of articular surface on; Wherein the body of this mould improves or separation with it from articular surface, so that make the accuracy of its position can not receive the influence of arthritis or other joint deformity.This mould can be retained on the part of one or more tibia sour jujubes or tibia sour jujube.Perhaps, can be designed to be retained in the variation that hyperosteogeny or other vegetation or disease cause with this mould is all or part of.
This template can be can be by the mould of plastics or polymer making.This mould can be processed through rapid shaping technique, wherein lays the continuous multilayer plastics, as as known in the art.In other embodiments, the part of this template or this template can be made of metal.Can use based on the manufacturing technology milling of laser or make this mould.
Can use rapid shaping and for example DEWAXING TECHNIQUE cast this template.Can also carry out milling to it.For example, can when beginning, use preforming mould, can it be milled into the exclusive size of patient then with common shape.Milling only can be carried out on a surface of mould, preferably carries out facing on the surface of articular surface.Can milling and rapid shaping technique combination be used.
Can use curable material, wherein can be injected in the mould that for example uses the rapid shaping generation.For example, can use liquid metal.Randomly the solidified material of milling maybe can use other technology that further fine processing is carried out on its surface.
Can metal insert be applied to plastic components.For example, the plastics mould can have at least one guide hole to accept reamer or saw.Can use metal insert to provide stiff wall portion to accept reamer or saw.Use this or similar design can serviceably avoid when saw or other operating theater instruments possibly contact with mould the time plastics or other chip in the joint, accumulate.Can also use other hard material to come as inserts.These can also comprise for example rigid plastics or pottery.
In another embodiment, this mould does not have metal insert to accept Counterboring apparatus or saw.Metal insert or guiding device can be the parts of the common attachment arrangement that contacts with mould.Therefore, metal awl guiding device or metal saw guiding device can for example have metal or hard dilator, and it passes mould, thus for example also stable phase be applied to any device of mould for the physics body of mould.
This template not only can be used for the placement and the orientation of assisting operation technology and guiding operating theater instruments.The placement that in addition, can also utilize these templates to guide graft, implant or implant parts.
Can in operation process, use one or more templates.Orthopaedic surgical operations doctor has implemented selected operation (like cutting, reaming, boring and/or other operation) and has made the skeleton or a part of template that are coupled to the joint afterwards, also is possible.This template can be included the skeleton of these operation generations or the shape in joint in consideration.
According to some embodiments, when the position of selecting (being not limited to) cutting planes, hole, groove and hole on template, can comprise relevant other joint or spool information and the alignment information of joint or limbs.Can use above-mentioned imaging technique to obtain biodynamics axle and/or anatomical axis; These imaging techniques comprise and are not limited to the standard actinogram; Comprise the load-bearing actinogram, for example upper right knee x actinogram or whole lower limb length portion's photo (for example, from the hip to the foot).Can adopt different projection orientation to obtain these actinograms, for example before and after, before the back, the outside, tiltedly side and/or other projection orientation.Can also use other imaging form (like the part or all of CT scan that passes limbs or MRI scanning, CT location scanning or the MRI partial sweep of form alone or in combination) to obtain biodynamics axle and anatomical axis, like what describe in the preceding text embodiment.For example, when imagining complete or part arthroplasty of knee, can pass knee joint and obtain CT scan.Pass kneed CT scan as generating the basis be attached to kneed part or all of concave surface profile template/mould.Hip and ankle joint be can pass and additional CT or MRI scanning obtained.For example barycenter or central point or other anatomic landmark in each joint of these scanning definition be can use, biodynamics axle and other axle obtained then.
In another embodiment, can use based on non-image method and set up the biodynamics axle, comprise conventional surgical apparatus and survey tool, for example rod in the marrow, aim at guiding device and also have surgical navigational.For example, in knee joint, can light or radio frequency sign be attached to limbs.Rotate lower limb around hip joint then, and can be for the position of different lower limb location records signs.Capital center can be confirmed in the center of rotation.Can confirm similar reference point at ankle joint and/or other position.Can optimize the position of template or more typically optimize the position of operating theater instruments to given biodynamics heavy burden pattern (turn over for example or turn up aim in) then with respect to template.Thus, through perform the operation preceding or operation in implement these and measure, can optimize the position of operating theater instruments with respect to mould, and can place cutting and proofread and correct the bottom axis error, turn in for example or the malalignment or lean forward or hypsokinesis of turning up.
When imaging, can generate physical template.This template can be used in the operation of carries out image guiding, like part or perfect joint replacement, articular resurfacing or ligament repair.This template can comprise reference point or opening or the hole that is used for operating theater instruments (like awl, saw, repair bone drill etc.).
For obtain holing preferably towards, can adjust opening or container in boring, cutting planes, saw plane etc., said template or the attachment region to include at least one axle in consideration.This can be the anatomical axis or the biodynamics axle of for example knee joint, hip joint, ankle joint, shoulder joint or elbow joint.
In one embodiment, only use an axle to place and optimize this type of boring, saw plane, cutting planes and/or other operation and get involved.This axle can be for example anatomical axis or biodynamics axle.In some embodiments, axle and/or planar combination can be used in and optimize the placement that boring, saw plane, cutting planes and/or other operation get involved.For example, can with two axles (for example, an anatomical axis and a biodynamics axle) as the position of the template of considering the 3D guiding and related accessories or connecting device, shape or towards factor.For example, can use two axles (for example, an anatomical axis and a biodynamics axle) and a plane (plane, top that for example, defines) by tibial plateau.Perhaps, can use like two or more planes (for example, coronal plane and sagittal plane) by image or the definition of patient's anatomical structure.
Can be one or more at these as expected, preferably two or more, preferably implement angle and distance in three or three the above planes and measure and measuring surface form.Inside the Pass can for example having obtained, these angular surveying turn over or valgus deformity, flexing or stretch defective, superflexion or flexing deficiency or hyperextension or hypometria, abduction, interior receipts, internal rotation or external rotation defective or hyperabduction or abduction is not enough, excessive or interior the receipts deficiency of interior receipts, internal rotation is excessive or internal rotation is not enough or external rotation is excessive or the insufficient information of external rotation.
Can utilize single or a plurality of axis or plane survey to come to get involved to confirm the preferred angle of proofreading and correct then through for example adjusting surgical cut or saw plane or other operation.Usually, the correction of two axles possibly be superior to the correction of an axle, and two planar corrections are superior to a planar correction, and by that analogy.
According to some embodiments, can be directed against particular treatment (the for example placement of articular surface rebuilding or replacement implant or parts) implement more than once hole, cutting, bore hole and/or reaming or other operation get involved.Relation according to biodynamics axle and/or anatomical axis and/or implantation axon is implemented these twice or twice above operation intervention (for example, boring, cutting, reaming, sawing).Guiding template or adnexa or connected connecting device comprise that two or more openings, guiding device, aperture or reference plane are with respect to biodynamics axle, anatomical axis, implantation axon or obtain thus or other relevant with it axle implements at least twice or twice above boring, reaming, bore hole, sawing or cutting.
In disposable use and reusable embodiment, can this instrument be designed to make the degree of depth and/or the direction of this apparatus keyhole, that is, awl can not reach than what apparatus allowed and deeper pierce tissue.
Preamble is described embodiment to explanation and purpose of description.It is not intended to detailed or limit the invention to disclosed concrete form.Many modifications, variation, combination and the increase of embodiment described herein is conspicuous to those skilled in the art, and many other embodiments also are possible.Under the prerequisite that does not deviate from by the defined the spirit and scope of the present invention of accompanying claims, the General Principle of this paper definition can be applicable to other embodiment and application.Therefore, the embodiment shown in the present invention is not intended to be limited to, but will meet and principle disclosed herein and characteristic the wideest consistent scope.In order to reach the disclosed degree required for the present invention of complete understanding, the patent of all announcements of quoting among the application, patent are announced and the description and the accompanying drawing mode by reference of patent application are incorporated this paper into.

Claims (20)

1. method that is used for ligament repair, said method comprises:
Obtain at least one surperficial electronic image data related with ligament; And
Construct first template based on said view data at least in part; Said template has at least one contact surface of at least a portion that meets said surface, and said template comprises at least one guiding device of the motion that is used to guide the related operating theater instruments of said ligament repair.
2. method according to claim 1, wherein said ligament is an anterior cruciate ligament.
3. method according to claim 1, wherein said ligament is a posterior cruciate ligament.
4. method according to claim 1 also comprises the position, tunnel of confirming the implantation of ligament thing.
5. method according to claim 4 confirms wherein that position, said tunnel comprises the starting point of the ligament on identification first articular surface and at the second joint lip-deep on position relative with said first articular surface.
6. method according to claim 4 confirms that wherein position, said tunnel comprises based in the remainder of said view data identification bony landmark and ligament at least one.
7. method according to claim 4, wherein said surface are one of surfaces adjacent with the non-bearing surface with position, said tunnel.
8. method according to claim 1, wherein said first template comprises the brill guide hole, said method also comprises:
Locate said template so that said at least one contact surface contacts with the said at least a portion on said surface; And
Get out the ligament tunnel, wherein by said brill guide hole pilot bore hole.
9. method according to claim 8, the shape of the said brill guide hole on wherein said first template, position and towards at least a at least in part based on the distance of said tunnel to adjacent cortical bone.
10. method according to claim 9, wherein said brill guide hole comprises stop, so that reach the drilling depth of expectation.
11. method according to claim 1 wherein obtains said view data before operation.
12. method according to claim 1 wherein obtains said view data through at least a in CT scan and the MRI scanning.
13. method according to claim 1, wherein joint flexing, joint stretching, extension, joint abduction, intraarticular receive and the joint rotation at least a the time obtain said view data.
14. method according to claim 1 also comprises:
Obtain the position based on said view data identification graft; And
Use said first template to guide to obtain the position and obtain at least one ligament and the skeleton from said graft.
15. method according to claim 1 also comprises:
Make second template and the said first template cross reference so that on the second surface related with said ligament, aim at the position of said second template, said second template comprises at least one guiding device; And
Use said at least one guiding device of said second template to guide of the motion of said operating theater instruments with respect to said guiding device.
16. method according to claim 15, wherein said first surface and second surface are relative articular surfaces.
17. method according to claim 16, wherein said first surface are femoral surface and said second surface is the tibia surface.
18. method according to claim 1, wherein said first template comprises tissue retractor.
19. method according to claim 18, wherein said tissue retractor are a kind of in flange and the dilator.
20. method according to claim 1 also is included in the said template of at least a middle use in ligament reconstruction of list bundle and the reconstruction of two-beam ligament.
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